CN113029917B - Cell and cell nucleus bioelectricity characteristic detection device and method - Google Patents
Cell and cell nucleus bioelectricity characteristic detection device and method Download PDFInfo
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Abstract
The invention provides a cell and cell nucleus bioelectricity characteristic detection device, comprising: the microfluidic chip comprises a narrow cross channel, wherein the narrow cross channel consists of a main channel and an auxiliary channel which are perpendicular to each other, the cross section of the main channel is smaller than that of a cell nucleus so as to compress the cell nucleus in a flowing cell, and the auxiliary channel is used for performing impedance detection; a pressure control module for applying pressure to pass the cells through the narrow cross-channel; and the impedance measurement module is used for measuring the amplitude and the phase of the dual-frequency impedance at the two ends of the auxiliary channel, and calculating the bioelectricity characteristic data of the cells and the cell nucleuses according to the amplitude and the phase. The detection device provided by the invention separates the electrical characteristics of the cell nucleus from the cell characteristics, and realizes high-throughput and accurate representation of the bioelectrical characteristics of the cell and the cell nucleus.
Description
Technical Field
The invention relates to the technical field of cell detection, in particular to a device and a method for detecting bioelectrical characteristics of cells and cell nucleuses.
Background
The bioelectrical characteristics of cells are of great significance for diagnosing blood and tumor diseases, etc. Further, the nucleus, the largest and most important cellular structure within the cell, plays a crucial role in the metabolism, growth and differentiation of the cell, and its bioelectrical properties are almost equally important.
The conventional methods for detecting the bioelectrical characteristics of the cell nucleus mainly comprise a patch clamp technology, a dielectric spectrum method, an electro-rotation method and the like. The working principle of the patch clamp technology is that a cell external Ag/AgCl electrode and two conical glass micro-tube electrodes are used for measuring the nuclear membrane specific capacitance and resistance. When measuring the nuclear membrane resistance, two microtubule electrodes are arranged in the nucleus of a cell, one electrode is used for transmitting current to cause the change of the nuclear membrane potential, and the other electrode is used for recording the change of the potential; when the nuclear membrane specific capacitance is measured, under the assistance of an Ag/AgCl electrode outside a cell, the time constants of the rise and the fall of the potential are recorded by moving one of the microtubule electrodes into a cell membrane, entering the nuclear membrane, penetrating the nuclear membrane and penetrating the cell membrane. The method has the defects of low detection flux and more suitability for measuring cell nuclei with larger sizes. The working principle of the dielectric spectrum method is that a sample cavity containing a cylindrical hole is regarded as a parallel plate capacitor, and meanwhile, pt electrodes are fixed on two sides of the parallel plate capacitor, and dielectric constants and conductivities under different frequencies are obtained by utilizing a proportional arm bridge to measure. The method has the advantage of simple operation, but has the defect that the measurement is based on the layer of population cells and can not obtain the bioelectrical characteristics of the single-cell nuclear organisms. The working principle of the electro-rotation method is that alternating voltage signals with the same amplitude and frequency and 90-degree phase difference are respectively applied to two pairs of electrodes which are perpendicular to each other. The cells are added between the electrodes, and can realize uniform rotation and keep balance under the action of the rotation torque and the fluid torque. By varying the frequency of the AC voltage signal applied to the electrodes, the variation of cell rotation speed with frequency (i.e., ROT spectrum) can be obtained using an inverted microscope and a high-speed camera. The method has the defect that the detection flux is low due to long time for manipulating and positioning the cells.
Methods for detecting the bioelectrical properties of cell nuclei based on microfluidics generally include dielectrophoresis methods based on microchannels, methods based on capture channels and methods based on in-line compression channels. The dielectrophoresis method based on the micro-channel has the working principle that a driving electrode and a sensing electrode are embedded at the bottom of a micro-fluid channel. When the cells pass through, the cells are subjected to dielectrophoresis force generated by the driving electrodes and induced to generate corresponding height displacement, and meanwhile, the sensing electrodes on the two sides of the driving electrodes are used for measuring the electric signal change caused by the height displacement change of the cells before and after the dielectrophoresis force is driven. This approach has the disadvantage that the lack of effective model support results in unreliable data. The method based on the capture channel has the working principle that when cells are captured in the capture channel region, the differential electrode pair is applied to detect the impedance spectrum, and finally the electrical characteristics of the cell nucleus are obtained. The drawback of this method is that the electrical properties of the cell nucleus cannot be decoupled from the cellular properties. The method based on the linear compression channel has the working principle that cell nucleuses with complete nuclear membrane electrical characteristics extracted by a conventional chemical method are captured at the inlet of the compression channel, frequency scanning is carried out by applying electrodes at two ends to obtain an impedance spectrum, and the electrical characteristics of the cell nucleuses are obtained by fitting. The difficulty of this method is that the number of effective nuclei extracted is small, limiting the throughput of detection.
Therefore, it is very meaningful to develop a novel device and method for detecting the bioelectrical characteristics of cells and cell nuclei accurately at high throughput.
Disclosure of Invention
Technical problem to be solved
Aiming at the problems, the invention provides a device and a method for detecting the bioelectrical characteristics of cells and cell nucleuses, which are used for at least partially solving the technical problems of low detection flux, inaccurate detection result and the like of the traditional method.
(II) technical scheme
The invention provides a cell and nucleus bioelectricity characteristic detection device, which comprises: the microfluidic chip comprises a narrow cross channel, wherein the narrow cross channel consists of a main channel and an auxiliary channel which are perpendicular to each other, the size of the cross section of the main channel is smaller than that of the cross section of a cell nucleus so as to compress the cell nucleus in a flowing cell, and the auxiliary channel is used for carrying out impedance detection; a pressure control module for applying pressure to pass the cells through the narrow cross-channel; and the impedance measurement module is used for measuring the amplitude and the phase of the dual-frequency impedance at the two ends of the auxiliary channel, and calculating the bioelectricity characteristic data of the cells and the cell nucleuses according to the amplitude and the phase.
Further, the microfluidic chip further comprises: a cell solution injection channel and a cell solution recovery channel which are respectively connected with two ends of the main channel and are used for enabling cells to normally flow; one of the cell solution injection channel and the cell solution recovery channel is also connected with the pressure control module.
Further, the microfluidic chip further comprises: the insulating substrate is provided with a metal electrode and is used for being connected with the impedance measuring module; the material comprises silicon chip, polymethyl methacrylate and polydimethylsiloxane.
Furthermore, the size of the cross section of the main channel ranges from 7 micrometers to 12 micrometers, and the size of the cross section of the auxiliary channel ranges from 2 micrometers to 3 micrometers.
Further, the height of the cross section of the cell solution injection channel and the cell solution recovery channel is in the range of 30 to 40 μm.
The invention also provides a preparation method of the cell and cell nucleus bioelectricity characteristic detection device, which comprises the following steps: s11, preparing a required micro-fluidic channel male die on a chromium-sputtered glass sheet through gluing, exposing and developing; s12, pouring the prepolymer and the curing agent on the microfluidic channel male mold, and curing and demolding to obtain PDMS containing the microfluidic channel; s13, punching holes at corresponding positions of PDMS containing the microfluidic channels, and bonding the holes with a glass substrate containing an on-chip electrode to obtain a microfluidic chip; and S14, connecting the micro-fluidic chip with the impedance measurement module and the pressure control module to obtain the cell and cell nucleus bioelectricity characteristic detection device.
In a further aspect of the present invention, there is provided a method for obtaining bioelectrical characteristic data by detecting with the aforementioned device for detecting bioelectrical characteristics of cells and cell nuclei, comprising: s21, adding a cell suspension into a narrow cross channel of the microfluidic chip, and applying negative pressure through a pressure control module to drive cells to pass through the narrow cross channel; s22, detecting impedance data between electrodes through an impedance measuring module; s23, calculating the cell and nucleus stretch length by:
wherein, t 1 Time for the cell to gradually and maintain the completely blocked electric field lines, t 2 Time for cell and nucleus to gradually block electric field lines completely, t 3 Time to maintain complete blocking of electric field lines for cells and nuclei, t 4 The time for blocking the gradual decrease of electric field lines for the cell and nucleus, t 5 Is a cellThe time for blocking the electric field lines to gradually decrease; w m Is the width of the main channel, W s Is the width of the secondary channel, L c Is cell elongation, L n Stretching the length for the cell nucleus; and S24, calculating according to the impedance data and the cell and cell nucleus stretching length data to obtain bioelectricity characteristic data, wherein the bioelectricity characteristic data comprises the nuclear-to-cytoplasmic ratio N to C, the cell membrane specific capacitance, the cytoplasm conductivity, the nuclear-to-membrane specific capacitance, the nuclear-to-membrane resistance and the nuclear-to-cytoplasmic conductivity.
Further, the formula of calculating the cell nucleus-to-cytoplasm ratio N: C in S24 is as follows:
further, the cell membrane specific capacitance C was calculated in S24 sm Cytoplasmic conductivity σ cp The formula of (1) is as follows:
wherein, C m As the cell membrane capacitance, R cp The cytoplasmic resistance is determined from the impedance magnitude phase data at two frequencies.
Further, the nuclear membrane specific capacitance C is calculated in S24 sne Nuclear membrane resistance R sne And nuclear mass conductivity σ np The formula of (1) is as follows:
wherein, C ne As nuclear membrane capacitance, R ne Is nuclear membrane resistance, R np The nuclear mass resistance is obtained by impedance amplitude phase data at two frequencies.
(III) advantageous effects
The device and the method for detecting the bioelectrical characteristics of the cells and the cell nucleuses provided by the embodiment of the invention utilize a pressure control module to apply negative pressure, suck the cells to pass through a narrow cross channel, utilize an impedance measurement module to detect the double-frequency impedance amplitude and the phase when the cells pass through at the two ends of a secondary channel in the cross channel, and utilize the impedance amplitude data at any frequency to obtain the stretching length of the cells and the cell nucleuses so as to obtain the nuclear-to-cytoplasmic ratio; and obtaining the cell membrane specific capacitance, the cytoplasm conductivity, the nuclear membrane specific capacitance, the nuclear membrane resistance and the nuclear mass conductivity by using the double-frequency impedance amplitude and phase data and the obtained cell and nucleus stretching length information. Compared with the existing method, the invention adopts an effective electrical model to separate the electrical characteristics of the cell nucleus from the characteristics of the cell, thereby realizing high-throughput and accurate representation of the bioelectrical characteristics of the cell and the cell nucleus.
Drawings
FIG. 1 is a schematic view showing the structure of a device for measuring bioelectrical characteristics of cells and cell nuclei according to an embodiment of the present invention;
FIG. 2 is a schematic view showing the structure of a microfluidic chip module in the device for detecting bioelectrical characteristics of cells and nuclei according to the embodiment of the present invention;
FIG. 3 is a schematic flow chart showing the processing of a microfluidic chip module in the device for detecting bioelectrical characteristics of cells and nuclei according to the embodiment of the present invention;
FIG. 4 is a schematic diagram illustrating a calculation principle of the stretch length of the cell and the cell nucleus in the method for detecting the bioelectrical characteristic of the cell and the cell nucleus according to the embodiment of the invention;
FIG. 5 is a schematic diagram showing an equivalent electrical model of cell and cell nucleus electrical characteristics detection in the cell and cell nucleus bioelectrical characteristics detection method according to the embodiment of the invention.
Detailed Description
In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to specific embodiments and the accompanying drawings.
An embodiment of the present invention provides a device for detecting bioelectrical characteristics of cells and cell nuclei, referring to fig. 1, including: the microfluidic chip comprises a narrow cross channel, wherein the narrow cross channel consists of a main channel and an auxiliary channel which are perpendicular to each other, the size of the cross section of the main channel is smaller than that of the cross section of a cell nucleus so as to compress the cell nucleus in a flowing cell, and the auxiliary channel is used for carrying out impedance detection; a pressure control module for applying pressure to pass the cells through the narrow cross-channel; and the impedance measurement module is used for measuring the amplitude and the phase of the dual-frequency impedance at the two ends of the auxiliary channel, and calculating the bioelectricity characteristic data of the cells and the cell nucleuses according to the amplitude and the phase.
The microfluidic chip module is a core module in a hardware device, and is formed by an insulating carrier and an insulating substrate through bonding operation, and a schematic structural diagram is shown in fig. 2. The narrow cross channel comprises a main channel and a secondary channel: the main channel structure is characterized in that the cross section of the main channel is smaller than that of cell nucleus so as to compress the cell nucleus in the flowing cell, and two ends of the auxiliary channel are electrically connected with the impedance measuring module. The insulating substrate of the microfluidic chip module mainly comprises metal electrodes. The overlapping area of the auxiliary channel and the upper electrode cannot be too small, so that the measuring effectiveness is prevented from being influenced by too large capacitive reactance of a double electric layer capacitor connected in series in the detection system. And bonding the subsequent insulating substrate and the insulating bearing body to obtain the microfluidic chip. The impedance measuring module comprises a phase-locked amplifier and a data acquisition card, the impedance measuring module can accurately detect whether the impedance changes according to the requirement of the embodiment, the output frequency is 100000 sampling points/second, and an interface connected with the microfluidic chip module is a metal clamp or other metal clamps. The pressure control module comprises a pressure controller and an air guide hose, wherein the pressure controller can output any pressure between-50 kPa and is connected with the micro-fluidic chip module through the air guide hose.
In the experimental operation of this embodiment, the microfluidic chip module, the impedance measurement module and the pressure control module are connected first. The connection method is that two ends of the impedance measurement module are respectively connected with the corresponding upper electrodes at two ends of the auxiliary channel in the narrow cross channel; the pressure output end of the pressure control module is connected to the cell solution recovery channel of the microfluidic chip module. All channels in the microfluidic chip were then filled with phosphate buffered saline PBS in order to prevent air bubbles from forming in the cell solution recovery channels of the microfluidic chip when pressure is applied through the channels, which would affect the flow of the cells. And then, adding a cell suspension liquid with a certain concentration into a cell solution injection channel of the microfluidic chip, applying negative pressure by using a pressure control module to drive cells to pass through a narrow cross channel, and simultaneously detecting impedance data when cells pass between electrodes by using an impedance measurement module to serve as original data of an experiment.
It should be noted that the structure of the microfluidic chip demonstrated in the present invention is a basic unit of the method, and parallel and serial arrangement of cells in the cell-passing direction can be conveniently performed, and even combination of some structures can bring different effects. The cross section of the channel in the microfluidic chip can be rectangular, circular or semicircular and the like, and the realization of the basic function is not influenced. In addition, the channel is formed by sealing the cover plate and the substrate, and the channel can be etched in materials such as glass, and the required functions can be realized.
On the basis of the above embodiment, the microfluidic chip further includes: a cell solution injection channel and a cell solution recovery channel which are respectively connected with two ends of the main channel and are used for enabling cells to normally flow; one of the cell solution injection channel and the cell solution recovery channel is also connected with the pressure control module.
The insulating bearing body of the microfluidic chip module sequentially comprises a cell solution injection channel, a narrow cross channel and a cell solution recovery channel. The cell solution injection channel is characterized in that the cross section is far larger than the cell diameter so as to ensure the normal flow of the cells, and the height of the cross section of the channel is about 30-40 mu m (the diameter of most cells is about 15-20 mu m). The cell solution recovery channel has the same structural features as the cell solution injection channel. The pressure controller is connected with the micro-fluidic chip module through the air guide hose, and can apply positive pressure at the end of the cell solution injection channel and negative pressure at the cell solution recovery channel.
On the basis of the above embodiment, the microfluidic chip further includes: the insulating substrate is provided with a metal electrode and is used for being connected with the impedance measuring module; the material comprises silicon chip, polymethyl methacrylate and polydimethylsiloxane.
The auxiliary channel in the narrow cross channel is connected with the metal electrode and used for detecting impedance amplitude data; the overlapping area of the auxiliary channel and the upper electrode cannot be too small, so that the capacitance reactance of a double electric layer capacitor connected in series in the detection system is prevented from being too large to influence the measurement effectiveness. The material of the substrate is a common substrate material, and is not limited to the above three materials, and other substrate materials can be used as the substrate of the present invention.
On the basis of the above embodiment, the cross-sectional size of the main channel ranges from 7 μm to 12 μm, and the cross-sectional size of the sub-channel ranges from 2 μm to 3 μm.
The diameter of the cell nucleus is 10-15 μm, and the cross section width of the main channel is in the range so as to compress the cell nucleus in the flowing cell; the secondary channel structure is characterized in that the cross section area is about 1/3 of the cross section area of the main channel generally, so that cells can not enter the secondary channel in the process of passing through, and meanwhile impedance detection can not be affected by overhigh impedance base line, the width of the cross section area is about 2-3 mu m generally, and the height of the cross section area is the same as that of the main channel.
On the basis of the above-described embodiment, the cross-sectional heights of the cell solution injection channel and the cell solution recovery channel are in the range of 30 to 40 μm.
The cell solution injection channel is characterized in that the cross section is far larger than the cell diameter so as to ensure the normal flow of the cells, and the height of the cross section of the channel is about 30-40 mu m (the diameter of most cells is about 15-20 mu m). The structural characteristics of the cell solution recovery channel are the same as those of the cell solution injection channel.
Another embodiment of the present invention provides a method for manufacturing a device for detecting bioelectrical properties of cells and cell nuclei, comprising: s11, preparing a required micro-fluidic channel male die on a chromium-sputtered glass sheet through gluing, exposing and developing; s12, pouring the prepolymer and the curing agent on the microfluidic channel male mold, and curing and demolding to obtain PDMS containing the microfluidic channel; s13, punching holes at corresponding positions of PDMS containing the microfluidic channels, and bonding the holes with a glass substrate containing an on-chip electrode to obtain a microfluidic chip; and S14, connecting the microfluidic chip with the impedance measurement module and the pressure control module to obtain the cell and cell nucleus bioelectricity characteristic detection device.
The microfluidic chip module processing flow is shown in fig. 3. Specifically, firstly, an AZ 1500 photoresist is spin-coated on a glass sheet sputtered with chromium (Cr), a mask with a chromium mark is formed after prebaking, exposing, developing and hardening, then chromium outside the mark is removed by using a chromium corrosion solution, then the photoresist of the remaining mask is removed, and finally the chromium mark is formed on the glass sheet, as shown in fig. 3-c. And then spin-coating a layer of SU 8-2 on the chromium glass sheet, and forming a seed layer after pre-baking, flood exposure and post-baking hardening, as shown in figure 3-d. Next, spin-coating a layer of SU 8-5 on the seed layer, pre-baking, exposing, post-baking, and developing-free, as shown in FIG. 3-e; and then, a layer of SU 8-25 is spin-coated on the basis, and the required micro-fluidic channel male die is formed by pre-baking, exposure, post-baking, development and film hardening, as shown in the attached figure 3-g, namely S11. Then, the mixture of the prepolymer of the polydimethylsiloxane polymer and the curing agent which are mixed according to the proportion and subjected to vacuum degassing is poured on a manufactured mould, as shown in the attached drawing 3-h, and the PDMS containing the microfluidic channel, namely S12, can be obtained after the solidification and demoulding. Then spin-coating AZ 1500 on the glass sheet, prebaking, exposing, developing to remove the photoresist at the electrode position, sputtering chromium/gold (Cr/Au) on the metal electrode as shown in figure 3-j, and then carrying out a stripping operation to obtain the on-chip electrode as shown in figure 3-k. And finally, punching a hole at the corresponding position of the obtained microfluidic channel, and bonding the punched hole with a glass substrate containing an on-chip electrode to obtain a complete microfluidic chip, as shown in the attached figure 3-1, namely S13. And connecting the micro-fluidic chip with the impedance measurement module and the pressure control module to obtain the cell and cell nucleus bioelectricity characteristic detection device, namely S14.
The material of the carrier of the present invention is PDMS, and the carrier may be formed using a material such as glass, SU-8, or a silicon wafer, in addition to PDMS.
In another embodiment of the present invention, a method for obtaining the bioelectrical characteristic data according to the aforementioned cell and cell nucleus bioelectrical characteristic detection apparatus comprises: s21, adding a cell suspension into a narrow cross channel of the microfluidic chip, and applying negative pressure through a pressure control module to drive cells to pass through the narrow cross channel; s22, detecting impedance data between electrodes through an impedance measuring module; s23, calculating the cell and nucleus stretch length by:
wherein, t 1 Time for the cell to gradually and completely block the electric field lines, t 2 Time for cell and nucleus to gradually and completely block electric field lines, t 3 Time to maintain complete blocking of electric field lines for cells and nuclei, t 4 The time for blocking the gradual decrease of electric field lines for the cell and nucleus, t 5 The time for blocking the gradual decrease of electric field lines for the cell; w m Is the width of the main channel, W s Is the width of the secondary channel, L c Is cell elongation, L n Stretch length for nucleus; and S24, calculating according to the impedance data and the cell and cell nucleus stretching length data to obtain bioelectricity characteristic data, wherein the bioelectricity characteristic data comprises the nuclear-to-cytoplasmic ratio N to C, the cell membrane specific capacitance, the cytoplasm conductivity, the nuclear-to-membrane specific capacitance, the nuclear-to-membrane resistance and the nuclear-to-cytoplasmic conductivity.
The cell and nucleus stretching length can be obtained by considering the impedance amplitude or phase change of any frequency when the cell passes through the narrow cross channel. The principle of cell and nucleus elongation calculation is shown in FIG. 4, wherein W is the impedance amplitude change at a single frequency m The width (height value is equal to width value), W, of main channel in narrow cross channel s Width of the secondary channel in the narrow cross channel, L c Is cell elongation, L n Is the nucleus stretched length. In this process, cells are inducedThe larger compression degree can be equivalent to a cuboid structure, and the limited compression of the cell nucleus is equivalent to a bar-shaped structure with two hemispheres at two ends, wherein the diameter of the hemisphere is the width value of the main channel. Before the cell passes through the channel as shown in figure 4-I-a, the cell does not block the electric field lines between the secondary channels, and the impedance amplitude is unchanged; as the cell travels between the positions shown in fig. 4-I-a and 4-I-b, the cell gradually blocks the electric field lines completely and the impedance amplitude rises; when the cell travels between the positions shown in FIGS. 4-I-b and 4-I-c, the cell remains completely blocked from the electric field lines and the impedance amplitude remains horizontal; as the cell passes between the positions shown in fig. 4-I-c and 4-I-d, the cell and nucleus gradually block the electric field lines completely and the impedance amplitude continues to rise; when the cell passes between the positions shown in FIGS. 4-I-d and 4-I-e, the cell and nucleus remain completely blocked from the electric field lines and the impedance amplitude continues to remain horizontal; when the cell passes between the positions shown in FIGS. 4-I-e and 4-I-h, the blocking electric field lines of the cell and the cell nucleus gradually decrease, the cell maintains the complete blocking electric field lines, and the blocking electric field lines of the cell gradually decrease, so that the impedance amplitude tends to decrease, maintain the level, and decrease again, contrary to the case when the cell passes between the positions shown in FIGS. 4-I-a and 4-I-d. According to the above analysis, when the cells sequentially pass through the positions shown in FIGS. 4-I-a-h, the impedance amplitudes will show the curves shown in FIGS. 4-II, and the cell-passing times t will be formed in a one-to-one correspondence 1 、t 2 、t 3 、t 4 And t 5 。
At t 2 Time period, cell movement displacement is the sum of half of the main channel width and the secondary channel width: w is a group of m /2+W s At t 3 The cell movement shift is the difference between the cell nucleus stretch length and the width of the main channel and the side channel: l is a radical of an alcohol n -W m -W s At t 4 Time period, cell movement shift is equivalent to t 2 Time period of W m /2+W s At t 1 ~t 5 The time period, the cell movement displacement is the sum of the cell stretching length and the width of the side channel: l is a radical of an alcohol c +W s 。
Considering that the length of the main channel in the narrow cross channel is small enough, the cells can be considered to keep moving at a constant speed during the course of their passage:
solving to obtain the cell and nucleus stretching length as follows:
further performing equivalent calculation according to the volume equivalent to obtain the cell diameter Dc and the cell nucleus diameter D n :
On the basis of the above examples, the formula of the karyocyte-to-cytoplasm ratio N: C is calculated as follows:
when no cell exists in the corresponding region of the secondary channel in the narrow cross channel, the equivalent electrical model is shown in figure 5-a, and the impedance between the electrodes can be the channel resistance Rc and the channel parasitic capacitance C c The parallel circuit of (1). The detection impedance is Z:
when only cells (without cell nucleus) are completely blocked in the corresponding area of the secondary channel in the narrow cross channel, the equivalent electrical model is as shown in figure 5-b, and considering that the cell membrane is formed by the mosaic adhesion of insulating phospholipid bilayer and membrane protein, the cell membrane presents the electrical property of capacitance, and the cytoplasm presents the electrical property of resistance, so the model of the cells in the cross channel is formed by the capacitance C of the detection area with specific area of the secondary channel m And a resistance R cp Forming; due to the fact thatA certain gap exists between the cell and the channel, so that a leakage resistance R is equivalently generated leak (ii) a Resistance of the cell-filled portion removed by the resistance value between the electrodes is represented by R c ' is represented by, i.e. R c -rR c Wherein the proportionality coefficient r can be obtained by finite element simulation, and still has the same effect as the channel parasitic capacitance C c And (4) connecting in parallel. At this time, the detection impedance Z:
the simultaneous formula 5 and formula 6 are substituted into the impedance amplitude phase data under two frequencies to obtain the cell membrane capacitance C m And cytoplasmic resistance R cp . Further, the specific capacitance C of the cell membrane is obtained sm And cytoplasmic conductivity σ cp :
When the corresponding region of the secondary channel in the narrow cross channel is completely blocked by the cell (including the nucleus), the equivalent electrical model is as shown in fig. 5-C, considering that the nucleus membrane is formed by the double-layer insulating phospholipid bilayer and the membrane protein mosaic, and the nucleus pore exists on the nucleus membrane, thus the electrical characteristics of capacitance and resistance are presented, the nucleus matter can be considered to present the electrical characteristics of resistance, so the model of the cell (including the nucleus) in the cross channel is formed by the cell membrane capacitance C of the detection region with the specific area of the secondary channel m Nuclear membrane capacitor C ne And a resistance R ne And nuclear resistance R np Composition is carried out; because a certain gap exists between the cell and the channel, a leakage resistance R is equivalent leak '; resistance of the cell-filled portion removed from the impedance value between the electrodes is represented by R c ' is represented by, i.e. R c -rR c Wherein the proportionality coefficient r can be obtained by finite element simulation, and still has the same effect as the channel parasitic capacitance C c And (4) connecting in parallel. At this time, the detection impedance Z:
the simultaneous formula 5, formula 6 and formula 8 are substituted into the impedance amplitude phase data of two frequencies, and then the nuclear membrane capacitor C can be obtained ne Nuclear membrane resistance R ne And nuclear mass resistance R np . Further, the nuclear membrane specific capacitance C is obtained sne Nuclear membrane resistance R sne And nuclear mass conductivity sigma np :
Up to this point, the present embodiment has been described in detail with reference to the accompanying drawings. Based on the above description, those skilled in the art should clearly understand that the device and method for detecting the bioelectrical characteristics of cells and cell nuclei based on narrow cross channels in the present invention.
Compared with the prior art, the invention does not need equipment such as a microscope and the like to operate and position the cells, thereby improving the detection flux of the electrical characteristics of the single cell nucleus; the cell nucleus is compressed through the narrow cross channel structure and separated from the cell characteristics, so that the detection accuracy of the electrical characteristics of the single cell nucleus is improved; the bioelectrical characteristics of cells and cell nucleuses can be effectively detected at the same time by a narrow cross channel and a corresponding equivalent electric model.
The above-mentioned embodiments are intended to illustrate the objects, technical solutions and advantages of the present invention in further detail, and it should be understood that the above-mentioned embodiments are only exemplary embodiments of the present invention, and are not intended to limit the present invention, and any modifications, equivalents, improvements and the like made within the spirit and principle of the present invention should be included in the protection scope of the present invention.
Claims (10)
1. A device for detecting the bioelectrical characteristics of cells and cell nuclei, comprising:
the microfluidic chip comprises a narrow cross channel, wherein the narrow cross channel is composed of a main channel and an auxiliary channel which are perpendicular to each other to form a cross-shaped structure, the size of the cross section of the main channel is smaller than that of the cross section of the cell nucleus so as to compress the cell nucleus in a flowing cell, and the auxiliary channel is used for impedance detection;
a pressure control module for applying pressure to pass cells through the narrow cross-channel;
the impedance measurement module is used for measuring the amplitude and the phase of the double-frequency impedance at the two ends of the auxiliary channel, and calculating the bioelectricity characteristic data of the cells and the cell nucleuses according to the amplitude and the phase; wherein the method of calculating the bioelectrical characteristic data comprises:
s21, adding a cell suspension into a narrow cross channel of the microfluidic chip, and applying negative pressure through the pressure control module to drive cells to pass through the narrow cross channel;
s22, detecting impedance data between electrodes through an impedance measuring module;
s23, calculating cell and nucleus stretch lengths by:
wherein, t 1 Time for the cell to gradually and completely block the electric field lines, t 2 Time for cell and nucleus to gradually block electric field lines completely, t 3 Time to maintain complete blocking of electric field lines for cells and nuclei, t 4 Time for blocking electric field lines from decreasing for cells and cell nuclei, t 5 The time for blocking the gradual decrease of electric field lines for the cell; w is a group of m Is the width of the main channel, W s Is the width of the secondary channel, L c Is the cell elongation, L n Stretch length for nucleus;
and S24, calculating according to the impedance data and the cell and cell nucleus stretching length data to obtain the ratio N to C of the nucleus to the cytoplasm, the ratio capacitance of the cell membrane, the cytoplasm conductivity, the ratio capacitance of the nuclear membrane, the nuclear membrane resistance and the nuclear cytoplasm conductivity.
2. The apparatus for detecting the bioelectrical characteristics of cells and nuclei according to claim 1, wherein the microfluidic chip further comprises:
a cell solution injection channel and a cell solution recovery channel which are respectively connected with two ends of the main channel and are used for enabling cells to normally flow;
one of the cell solution injection channel and the cell solution recovery channel is also connected with the pressure control module.
3. The apparatus for detecting the bioelectrical characteristics of cells and nuclei according to claim 2, wherein the microfluidic chip further comprises:
the insulating substrate is provided with a metal electrode and is used for being connected with the impedance measuring module; the material comprises silicon chip, polymethyl methacrylate and polydimethylsiloxane.
4. The apparatus for detecting the bioelectrical characteristics of cells and nuclei according to claim 1, wherein the cross-sectional dimension of the main channel is in a range of 7 μm to 12 μm, and the cross-sectional dimension of the sub-channel is in a range of 2 μm to 3 μm.
5. The apparatus for detecting the bioelectrical characteristics of cells and nuclei according to claim 2, wherein the height of the cross-section of the cell solution injecting passage and the cell solution collecting passage is in the range of 30 to 40 μm.
6. A method for preparing a cell and cell nucleus bioelectricity characteristic detection device comprises the following steps:
s11, preparing a required micro-fluidic channel male die on a chromium-sputtered glass sheet through gluing, exposing and developing;
s12, pouring a prepolymer and a curing agent on the micro-fluidic channel male die, and curing and demolding to obtain PDMS (polydimethylsiloxane) containing a micro-fluidic channel; the microfluidic channel comprises a narrow cross channel which is composed of a main channel and an auxiliary channel which are vertical to each other to form a cross-shaped structure, and the size of the cross section of the main channel is smaller than that of the cross section of the cell nucleus;
s13, punching holes at corresponding positions of the PDMS containing the microfluidic channel, and bonding the PDMS with a glass substrate containing an on-chip electrode to obtain a microfluidic chip;
s14, connecting the micro-fluidic chip with an impedance measurement module and a pressure control module to obtain a cell and cell nucleus bioelectricity characteristic detection device; wherein the method of calculating the bioelectrical characteristic data using the cell and nucleus bioelectrical characteristic detecting apparatus comprises:
s21, adding a cell suspension into a narrow cross channel of the microfluidic chip, and applying negative pressure through the pressure control module to drive cells to pass through the narrow cross channel;
s22, detecting impedance data between electrodes through an impedance measuring module;
s23, calculating the cell and nucleus stretch length by:
wherein, t 1 Time for the cell to gradually and completely block the electric field lines, t 2 Time for cell and nucleus to gradually block electric field lines completely, t 3 Time to maintain complete blocking of electric field lines for cells and nuclei, t 4 The time for blocking the gradual decrease of electric field lines for the cell and nucleus, t 5 The time for blocking the gradual decrease of the electric field lines for the cell; w m Is the width of the main channel, W s Is the width of the secondary channel, L c Is cell elongation, L n Stretch length for nucleus;
and S24, calculating according to the impedance data and the cell and cell nucleus stretching length data to obtain the ratio N to C of the nucleus to the cytoplasm, the ratio capacitance of the cell membrane, the cytoplasm conductivity, the ratio capacitance of the nuclear membrane, the nuclear membrane resistance and the nuclear cytoplasm conductivity.
7. A method for obtaining the bioelectrical characteristic data by the bioelectrical characteristic measuring apparatus of the cell and the cell nucleus according to any one of claims 1 to 5, comprising:
s21, adding a cell suspension into a narrow cross channel of the microfluidic chip, and applying negative pressure through the pressure control module to drive cells to pass through the narrow cross channel;
s22, detecting impedance data between electrodes through an impedance measuring module;
s23, calculating the cell and nucleus stretch length by:
wherein, t 1 Time for the cell to gradually and completely block the electric field lines, t 2 Time for cell and nucleus to gradually block electric field lines completely, t 3 Time to maintain complete blocking of electric field lines for cells and nuclei, t 4 The time for blocking the gradual decrease of electric field lines for the cell and nucleus, t 5 The time for blocking the gradual decrease of the electric field lines for the cell; w m Is the width of the main channel, W s Is the width of the secondary channel, L c Is cell elongation, L n Stretch length for nucleus;
and S24, calculating according to the impedance data and the cell and cell nucleus stretching length data to obtain the ratio N to C of the nucleus to the cytoplasm, the ratio capacitance of the cell membrane, the cytoplasm conductivity, the ratio capacitance of the nuclear membrane, the nuclear membrane resistance and the nuclear cytoplasm conductivity.
9. the method for detecting and obtaining data of bioelectrical characteristics according to claim 7, wherein a cell membrane specific capacitance C is calculated in said S24 sm Cytoplasmic conductivity σ cp The formula of (1) is as follows:
wherein, C m As the cell membrane capacitance, R cp The cytoplasmic resistance is found from the impedance magnitude phase data at two frequencies.
10. The method for detecting bioelectrical characteristic data according to claim 7, wherein the specific nuclear membrane capacitance C is calculated in S24 sne Nuclear membrane resistance R sne And nuclear matter conductivity σ np The formula of (1) is as follows:
wherein, C ne As nuclear membrane capacitance, R ne Is nuclear membrane resistance, R np Is a nuclear resistance passing two frequenciesAnd obtaining the lower impedance amplitude phase data.
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